Deployable receptacle

ABSTRACT

A deployable receptacle includes a tray for supporting an object thereon and being movable between a storing position and a deploying position. The tray stores an object thereon when the tray is disposed in the storing position and deploys the object therefrom when the tray is disposed in the deploying position. A lever is coupled to the tray for moving the tray between the storing position and the deploying position.

The present application is a continuation-in-part of U.S. applicationSer. No. 10/708,955 entitled “AN INTEGRATED TRANSPORT SYSTEM AND METHODFOR OVERHEAD STOWAGE AND RETRIEVAL,” and filed on Apr. 2, 2004.

BACKGROUND OF INVENTION

The present invention relates generally to aircrafts, and moreparticularly to an integrated transport system and method for moving anobject within a bi-level cabin.

Aircraft manufacturers are well known for producing aircrafts havingconstructions that maximize the use of space within those aircrafts. Forexample, certain commercial airplanes can have automated elevatorsystems for vertically moving galley carts between a main deck galleyand a lower lobe of the airplane. In this way, the galley carts can bestored in the lower lobe. For that reason, the main-deck passenger cabincan be sized larger than it would otherwise have been if those cartswere stored on the main deck. This construction is beneficial because itcan allow the manufacturer to increase the number of passenger seats,maintain the number of seats while increasing the size of the passengerseats, increase the room within which the passengers and the crewmemberscan move about the aircraft, or provide various other advantages.

Furthermore, a typical galley cart can weigh a substantially high amountand therefore can be somewhat cumbersome to store, retrieve, orotherwise manipulate within an aircraft. This substantially high weighttypically is attributed to the meals, beverages, trash, and variousother items carried by the cart, as well as the cart itself. Forinstance, one skilled in the art understands that a typical galley cartcan weigh up to about 250 pounds or more.

Therefore, it would be desirable to further improve the movement ofgalley carts, cargo, or other objects within a vehicle or building, andenhance the use of space within that vehicle or building.

SUMMARY OF INVENTION

One embodiment of the present invention is an integrated transportsystem for moving an object in an aircraft between a main cabin and anoverhead cabin via a shaft in connection therebetween. This integratedtransport system includes a single-unit gantry-lift device with anobject carrier for receiving the object. This object carrier has one ormore restraint members for securing the object in the object carrier andpreventing the object from tipping. The single-unit gantry-lift devicefurther includes a lift device for moving the object carrier generallyalong a longitudinal axis of the shaft. Moreover, thesingle-unit-gantry-lift device also includes a gantry device for movingthe object carrier generally along a first axis of the overhead cabinand/or a second axis, which is disposed generally perpendicular to thefirst axis.

One advantage of the invention is that an integrated transport system isprovided that can transfer a substantially heavy object with asubstantially low risk of the object tipping and falling.

Another advantage of the present invention is that an integratedtransport system is provided that can quickly and easily move an objectwithin an aircraft.

Yet another advantage of the present invention is that an integratedtransport system is provided with a simple construction for providingease of manufacture, minimizing the costs associated therewith, andfacilitating the installation of the integrated transport system.

Still another advantage of the present invention is that an integratedtransport system is provided that can increase the available space on amain deck of an aircraft.

Yet another advantage of the present invention is that an integratedtransport system is provided that can preserve the payload capacity of alower lobe or cargo bay of an aircraft.

Still another advantage of the present invention is that an integratedtransport system is provided that can be manually operated foreliminating the power requirements, maintenance costs, and likelihood ofmalfunctions, which are typically associated with automated transportsystems.

The features, functions, and advantages can be achieved independentlyand in various embodiments of the present invention or may be combinedin yet other embodiments.

BRIEF DESCRIPTION OF DRAWINGS

For a more complete understanding of this invention, reference shouldnow be made to the embodiments illustrated in greater detail in theaccompanying drawings and described below by way of examples of theinvention:

FIG. 1 is a perspective view of an aircraft having a bi-level galleymodule with an integrated transport system, according to one embodimentof the claimed invention;

FIG. 2 is a perspective view of the bi-level galley module shown in FIG.1;

FIG. 3A is a perspective view of an overhead sub-module of the bi-levelgalley module shown in FIG. 2;

FIG. 3B is a perspective view of a main-deck sub-module of the bi-levelgalley module shown in FIG. 2;

FIGS. 4A-4D are partially cutaway perspective views of the bi-levelgalley module shown in FIG. 2, sequentially illustrating the integratedtransport system moving a galley cart from the main-deck sub-module tothe overhead sub-module for storage therein;

FIG. 5A is a cross-sectional view of a gantry device of the integratedtransport system, shown in FIGS. 4A-4D;

FIG. 5B is a cross-sectional view of a gantry device of the integratedtransport system, shown in FIGS. 4A-4D, according to anotheradvantageous embodiment of the claimed invention;

FIG. 6 is a perspective view of the cart carrier, shown in FIGS. 4A-4D,with an unloading mechanism for unloading the galley cart, according toone advantageous embodiment of the claimed invention;

FIG. 7 is a partially cutaway plan view of the unloading mechanism shownin FIG. 6;

FIG. 8 is a cutaway view of the unloading mechanism shown in FIG. 7, astaken along line 8-8;

FIG. 9 is a perspective view of the cart carrier, shown in FIGS. 4A-4D,and an unloading mechanism for unloading the galley cart from the cartcarrier, according to another advantageous embodiment of the claimedinvention;

FIG. 10 is a perspective view of the cart carrier, shown in FIGS. 4A-4D,with an unloading mechanism for unloading the galley cart, according tostill another advantageous embodiment of the claimed invention;

FIG. 11A is a perspective view of a deployable receptacle for storingthe galley cart in the storage area of the overhead sub-module shown inFIGS. 4A-4D;

FIG. 11B is an exploded view of the deployable receptacle shown in FIG.11A;

FIG. 12 is a cutaway perspective view of the deployable receptacle shownin FIGS. 11A and 11B, illustrating the deployable receptacle moving thegalley cart from the receptacle to the cart carrier;

FIG. 13 is a side view of the deployable receptacle shown in FIGS. 11Aand 11B, illustrating the deployable cart being movable between astoring position and a deploying position;

FIG. 14A is a cutaway view of the deployable receptacle shown in FIG.13, as taken within circle 14A, illustrating a pivotal coupling formoving the deployable receptacle between the storing position and thedeploying position;

FIG. 14B is a cutaway view of the deployable receptacle shown in FIG.14A, illustrating the pivotal coupling according to another advantageousembodiment of the claimed invention;

FIG. 14C is a cutaway view of the deployable receptacle shown in FIG.14A, illustrating the pivotal coupling according to yet anotheradvantageous embodiment of the claimed invention;

FIG. 15 is a cutaway perspective view of the overhead sub-module with aseries of the deployable receptacles shown in FIGS. 11A and 11B;

FIG. 16 is a front view of the deployable receptacle shown in FIG. 11Awith a galley cart supported thereon; and

FIG. 17 is a logic flow diagram illustrating a method for operating theintegrated transport system shown in FIG. 4A-4D.

DETAILED DESCRIPTION

In the following figures the same reference numerals are utilized fordesignating the same or similar components in the various views.Moreover, the illustrated embodiments described herein employ featureswhere the context permits, e.g. when a specific result or advantage ofthe claimed invention is desired. Specifically, the embodimentsdescribed herein implement an integrated transport system for moving agalley cart between an overhead sub-module and a main-deck sub-module ofa bi-level galley module that is installed in an aircraft. However, itis contemplated that the integrated transport system can be utilized forvarious other suitable vehicles, buildings, and other environments thatrequire overhead storage. In addition, it will be appreciated that theintegrated transport system can be utilized for moving a variety ofsuitable objects besides galley carts. In this vein, various embodimentsare contemplated having different combinations of the describedfeatures, having features other than those described herein, or lackingone or more of those features. For these reasons, it is understood thatthe invention can be carried out in various suitable modes.

Referring to FIG. 1, there is shown a commercial airplane 10 having abi-level galley module 12 with an integrated transport system 14 (bestshown in FIGS. 4A-4D), according to one advantageous embodiment of theinvention. With attention to FIG. 2, the bi-level galley module 12includes a main-deck sub-module 16 (best shown in FIG. 3A) and anoverhead sub-module 18 (best shown in FIG. 3B) that is disposed abovethe main-deck sub-module 16. However, it will be appreciated that theairframe of the airplane 10 can instead define a bi-level galley invarious other suitable constructions besides a modular one.

The bi-level galley module 12 is utilized for storing a series of galleycarts 20 in the main-deck sub-module 16 and/or the overhead sub-module18. In this way, the bi-level galley module 12 can store about twice asmany galley carts 20 as a single-level galley module having asimilarly-sized perimeter. This feature is beneficial because it candecrease the overall number of galleys in the airplane and increase theamount of available space on the main deck. One skilled in the art willunderstand that this additional space can be utilized for hostingadditional passenger seats, maintaining the same number of passengerseats while increasing their size, increasing the available room withinwhich the passengers and the crewmembers can move about the airplane 10,providing various other advantages, or any suitable combination thereofas desired. In addition, in this embodiment, it will be appreciated thatthis bi-level galley module 12 does not occupy any space in the lowerlobe or cargo bay of the airplane 10. In this regard, the bi-levelgalley module 12 is further beneficial for preserving the payloadcapacity of the airplane 10. For these reasons, it is understood thatthe integrated transport system 14 can improve the efficiency of theairplane 10 as a vehicle for transporting persons, luggage, and variousother items. It is also understood that the bi-level galley module 12can store various other suitable objects besides galley carts 20 asdesired.

Referring now to FIGS. 4A-4D, there generally is shown the sequentialoperation of the integrated transport system 14 for storing a galleycart 20 in the overhead sub-module 18. Specifically, FIG. 4A shows thegalley cart 20 being secured to the integrated transport system 14.Furthermore, FIG. 4B illustrates the integrated transport system 14moving the galley cart 20 upward generally along a longitudinal axis 22of a shaft 24, which extends between the main-deck sub-module 16 and theoverhead sub-module 18. Additionally, FIG. 4C shows the integratedtransport system 14 moving the galley cart 20 along a first axis 26 ofthe overhead sub-module 18. Finally, FIG. 4D illustrates the integratedtransport system moving the galley cart 20 generally along a second axis28 for placing the galley cart 20 in a storage area 30 of the overheadsub-module 18.

Referring back to FIG. 4A, the integrated transport system 14 includes acart carrier 32 for receiving the galley cart 20. This cart carrier 32includes one or more restraint members for securing the galley cart 20to the cart carrier 32 and preventing the galley cart 20 from tippingover or otherwise falling from the cart carrier 32. This feature isadvantageous because it can substantially improve the safety of storing,retrieving, or otherwise transporting galley carts, which can weigh inup to 250 pounds or more.

In this embodiment, the restraint members are a series of interconnectedplate members 34, which form a box construction defining the cartcarrier 32. These plate members 34 are integral parts of the one-piecebox construction. However, it will be appreciated that the plate members34 can be separate components welded or otherwise fastened together byvarious suitable fasteners. Furthermore, it is also contemplated thatthe restraint members can instead be netting members, belt members, ropemembers, or any combination thereof as desired. In addition, it is alsounderstood that the cart carrier 32 can have other suitable shapesbesides a box construction.

The box construction includes one or more opposing open faces 36 forallowing the galley cart 20 to enter or exit the cart carrier 32. One ormore rope members 38 can be secured across the open faces 36 viasuitable fasteners, e.g. a cord with a hook-and-loop fastener, forpreventing the galley cart 20 from moving out of the cart carrier 32.Furthermore, as detailed in the description got FIG. 4D, one or more ofthe plate members 34 has one or more openings 40 formed therethrough forallowing a crewmember to reach into the cart carrier 32, grab hold ofthe galley cart 20, and manually force the galley cart 20 out of thecart carrier 32. It will also be appreciated that these openings 40 candecrease the amount of material comprising the cart carrier 32 therebydecreasing the material costs of the cart carrier 32, and minimizing theamount of weight carried by the airplane 10.

Referring back to FIG. 4B, the single-unit gantry-lift device 46 furtherincludes a lift device 46 coupled to the cart carrier 32 for raising andlowering the cart carrier 32 along the longitudinal axis 22 of the shaft24. In this way, the cart carrier 32 and the galley cart 20 containedtherein can be moved between the main-deck sub-module 16 and theoverhead sub-module 18. This lift device 46 is a motorized pulleymechanism. However, it is contemplated that the lift device 46 caninstead be a screw mechanism, a gear mechanism, manually operated orotherwise, or any suitable combination thereof as desired.

Moreover, the single-unit gantry-lift device 46 further includes agantry device 44, which is coupled to the lift device 46. As best shownin FIG. 4C, this gantry device 44 is utilized for moving the lift device46 and the cart carrier 32 along the first axis 26 of the overheadsub-module 18 to a point adjacent to an open or available section of thestorage area 30. Specifically, a crewmember can climb a ladder 48, enterthe overhead sub-module 18 via a walkway 50 in the overhead sub-module18, grab hold of one or more handles 52 extending from the cart carrier32, and pull the cart carrier 32 along the first axis 26. In this way,the crew member can utilize the gantry device 44 for moving the galleycart 20 next to its final destination in the storage area 30.

To that end, the gantry device 44 includes a pair of rails 54, which ismounted to the overhead sub-module 18 via bolt fasteners or othersuitable fasteners. These rails 54 are utilized for suspending the liftdevice 46 and the cart carrier 32 therefrom and preventing the cartcarrier 32 from tipping and causing the galley cart 20 to fall from thecart carrier 32. Moreover, in accordance with the aforementioned, eachrail 54 is substantially aligned with the first axis 26 of the overheadsub-module 18 for moving the lift device 46 and the cart carrier 32along the first axis 26 of the overhead sub-module 18.

As best shown in FIG. 5A, these rails 54 and the lift device 46 have twoor more rolling members 56 coupled therebetween. In this respect, afifth-percentile female can apply a substantially low force for movingthe lift device 46, the cart carrier 32, and a substantially heavygalley cart 20 along the first axis 26. In this embodiment, rollingmembers 56 are conventional wheels that are secured within a track 58defined by each rail 54. Each wheel and each respective rail 54 have aball-bearing coupling 56′ therebetween for minimizing the force requiredto move the lift device 46 and the cart carrier 32 along the rails 54.However, it is understood that other suitable rotatable couplings can beutilized as desired.

In another embodiment shown in FIG. 5B, the rails 54 and the lift device46 have one or more sliding members 60 coupled therebetween. Thesesliding members 60 are truncated tubes secured within the tracks 58.These truncated tubes have a cross-sectional shape that is substantiallysimilar to the cross-section of the rail 54. Additionally, the outersurface 62 of the truncated tube and the inner surface 64 of the track58 are sufficiently smooth for allowing the truncated tubes to slidesubstantially across the length of the rails 54. It is contemplated thata variety of other suitable low-friction couplings besides slidingmembers 60 and rolling members 56 can be utilized as desired.

Referring back to FIG. 4D, the crewmember can reach through the opening40 in the plate member 34, grab hold of the galley cart 20, and move thegalley cart 20 along the second axis 28 between the cart carrier 32 andthe storage area 30 of the overhead sub-module 18.

In another embodiment, the cart carrier 32 includes an unloadingmechanism for selectively attaching to the galley cart 20 and forcingthe galley cart 20 out of the cart carrier 32. For example, as shown inFIG. 6, the unloading mechanism is a gear system 72 integrated withinthe cart carrier 32 and a fastener 82 coupled to the gear system 72. Thegear system 72 includes a crank 74 for operation by a user. This crank74 drives a one or more gears 76 coupled together via one or more chains78. As best shown in FIGS. 7 and 8, each gear 76 has teeth 80 forcontacting opposing teeth 80′ formed in the fastener 82. This fastener82 is selectively coupled to the galley cart 20 for forcing the galleycart 20 out of the cart carrier 32 in a direction generally along thesecond axis 28. As best shown in FIG. 8, the fastener 82 is an overheadtray with a pair of side rail portions 84, which slide within respectivegrooves 88 formed within the cart carrier 32. Furthermore, the side railportions 84 include one or more detents 86 (shown in FIG. 6) forcontacting the cart carrier 32 and preventing the overhead tray fromsliding out of the grooves 88 and completely detaching from the cartcarrier 32. In addition, as shown in FIG. 6, the overhead tray hasopposing end portions 90 with a movable hook 92 coupled thereto forselectively attaching to an end of the galley cart 20. However, it iscontemplated that the gear mechanism 72 and the fastener 82 can havevarious other suitable constructions as desired.

By way of another example illustrated in FIG. 9, the unloading mechanismcan be a robotic arm 94 for grabbing hold of the galley cart 20extracting the galley cart 20 from the cart carrier 32. This robotic arm94 is pneumatically driven by way of a piston-driven mechanism or othersuitable pressure source. However, it will be appreciated that therobotic arm 94 can instead be driven by a hydraulic power source, anelectric servo motor, manual operation, any combination thereof, orvarious other suitable power sources as desired. It is also contemplatedthat the robotic arm 94 can push the galley cart 20 out of the carrier32 instead of pulling the galley cart 20 therefrom as desired.

According to yet another example shown in FIG. 10, the unloadingmechanism can be a bar member 96 positioned across an end of the galleycart 20. This bar member 96 can include a handle portion 98 for allowingan individual to force the bar member 96 and the galley cart 20 in adirection substantially along the second axis 28 of the overheadsub-module 18. It will be appreciated that a variety of suitableunloading mechanisms can be utilized for unloading the galley cart 20from the cart carrier 32 as desired.

Referring to FIGS. 11A and 11B, there are shown perspective assembledand exploded views of a deployable receptacle 100 for storing the galleycart 20, according to one advantageous embodiment of the claimedinvention. In this embodiment, the deployable receptacle 100 is utilizedfor storing a galley cart 32 and deploying a galley cart 32 therefrom.However, it is contemplated that the deployable receptacle 100 can beutilized for storing and deploying a variety of other suitable objectsas desired.

As best shown in FIGS. 12 and 13, the deployable receptacle 100 can betilted at a predetermined angle for causing the galley cart 20 to rollout of the receptacle 100 into the cart carrier 32 or otherwise decreasethe amount of force required to move the galley cart 20 into the cartcarrier 32. This feature is beneficial because it can facilitate aperson in moving a substantially heavy galley cart 32.

The deployable receptacle 100 includes a tray 102 for supporting thegalley cart 20 thereon. As introduced above, this tray 102 is movablebetween a storing position for storing the galley cart 20 thereon and adeployable position for deploying the galley cart 20 therefrom. Thistray 102 is substantially horizontal when it is disposed in the storingposition, and is tilted at a predetermined angle, e.g. up to fivedegrees, when it is disposed in the deploying position. However, it willbe appreciated that other suitable positions can be utilized instead.

The tray 102 has one or more levers 104 coupled thereto for moving thetray 102 between the storing position and the deploying position.Specifically, the tray 102 includes a proximal end portion 106 and adistal end portion 108 opposite to the proximal end portion 106. Inaddition, the lever 104 is comprised of a force arm 110, a resistancearm 112, and a fulcrum portion 114 therebetween. The resistance arm 112of the lever 104 is coupled to the distal end portion 108 of the tray102 for raising or lowering the distal end portion 108 of the tray 102.In this embodiment, the fulcrum portion 114 is pivotally coupled to adistal anchor member 116, which is fixedly mounted to a surface 30′ ofthe storage area 30. In this way, the lever 104 forces the distal endportion 108 of the tray 102 to move along a generally upward arcuatepath. For this reason, the resistance arm 112 preferably issubstantially horizontal when the tray 102 is midway between the storingposition and the deploying position. As one skilled in the art willunderstand, this feature can maximize the amount by which the tray 102is tilted while minimizing the amount of lever rotation for doing so.Additionally, in this embodiment, the force arm 110 has a pedal portion134 attached thereto for allowing an operator to step on the pedalportion 134 and move the tray 102 between the storing position and thedeploying position. However, it is understood that the lever 104 caninstead be actuated by a variety of other suitable mechanisms. Forinstance, a solenoid device, a hydraulic device, an electronic servodevice, other suitable mechanisms, or any combination thereof canactuate the lever 104 as desired.

The proximal end portion 106 of the tray 102 is coupled to a proximalanchor member 120 via a linkage bar 122. As mentioned above, theproximal anchor member 120 is attached to the surface 30′ of the storagearea 30. In this way, the proximal anchor member 120 secures the tray102 to surface 30′ of the storage area 30 while allowing the tray 102 tobe tilted as the distal end portion 108 is pivoted generally along itsarcuate path. As shown in FIG. 14A, the linkage member 122 has a firstend 122′ and a second end 122″ that is opposite to the first end 122′.In this embodiment, the first end 122′ is pivotally coupled to the tray102, and the second end 122″ is pivotally coupled to the proximal anchormember 120. In this way, the tray 102, the linkage bar 122, and theproximal anchor member 120 are configured for moving the proximal endportion 106 of the tray 102 along an arcuate path upward and thendownward to the original height. Specifically, the linkage bar 122preferably is substantially vertical when the tray is midway between thestoring position and the deploying position. For that reason, theproximal end portion 106 is positioned at the same height in the storingposition as it is in the deploying position. This feature isadvantageous because it allows the tray 102 to be aligned with the cartcarrier 32 when the tray 102 is in both the deploying position and thestoring position. In this regard, the galley cart 20 can be smoothlytransferred between the cart carrier 32 and the tray 102 without havingto first lift the galley cart before rolling the galley cart into thereceiving container.

In another embodiment as shown in FIG. 14B, the first end 122′ of thelinkage bar 122 is pivotally coupled to the proximal anchor member 120,and the second end 122″ of the linkage bar 122 is pivotally coupled tothe tray 102. For that reason, it will be appreciated that the tray 102,the linkage bar 122, and the proximal anchor member 120 are configuredfor moving the proximal end portion 106 along an arcuate path, generallydownward and then upward to the original height.

Also, as shown in another embodiment illustrated in FIG. 14C, theproximal end portion 106 can be coupled to the surface 30′ of thestorage area 30 via a slot and pin fastening pair 122′″ integratedwithin the proximal anchor member 120. However, it is understood thatvarious other constructions can be utilized for coupling the proximalend portion 106 of the tray 102 to the surface 30′ of the storage area30.

Referring now to FIGS. 15 and 16, the tray 102 includes a series ofroller members 124 extending from a pair of ledge portions 126 of thetray 102 for supporting a bottom portion 128 of the galley cart 20,according to one embodiment of the claimed invention. These rollermembers 124 allow the galley cart 20 to readily move into the tray 102when the tray 102 is in the storing position and also to readily movethe galley cart 20 out of the tray 102 when the tray 102 is tilted inthe deploying position. However, in another embodiment, the tray 102 haspan portion 130 upon which the wheels 132 of the galley cart 20 aresupported. In that way, the tray 102 allows the wheels 132 of the galleycart 20 to roll across the pan portion 130 as the galley cart 20 ismoved between the deployable receptacle 100 and the cart carrier 32.

Referring now to FIG. 17, there is shown a logic flow diagram for amethod for operating the integrated transport system 14 shown in FIGS.4A-4D. The method begins in step 200 and then immediately proceeds tostep 202.

In step 202, the galley cart 20 is secured to the cart carrier 32. Inthis embodiment, this step is accomplished by rolling the galley cart 20onto the cart carrier 32 through an open face 36 of the box constructioncomprising the cart carrier 32. As explained above, the cart carrier 32has one or more restraint members for securing the galley cart 20 to thecart carrier 32. These restraint members are a series of interconnectedplates 34, which define the cart carrier 32 itself. Additionally, therestraint members include a rope member 38 is secured across the openface 36 to prevent the galley cart 20 from inadvertently rolling throughthe open face 36 and out of the cart carrier 32. However, as explainedabove, the restraint members can be various other suitable mechanisms asdesired. Then, the sequence proceeds to step 204.

In step 204, a crewmember operates the lift device 46 for moving thecart carrier 32 and the galley cart 20 upward along the longitudinalaxis 22 of the shaft 24. This lift device 46 is a motorized pulleymechanism with sufficient power for lifting the cart carrier 32 and asubstantially heavy galley cart 20. However, it is contemplated that thelift device 46 can be various other suitable mechanisms, motorized ormanually operated, as described herein-above. Then, the sequenceproceeds to step 206.

In step 206, the crewmember climbs the ladder 48 and enters the overheadsub-module 18 via the walkway 50. This crewmember stands on the walkway50 and waits for the cart carrier 32 to arrive within the overheadsub-module 18. The sequence then proceeds to step 208.

In step 208, the crewmember operates the gantry device 44 for moving thelift device 46, the cart carrier 32, and the galley cart 20 along thefirst axis 26 of the overhead sub-module 18. This gantry device 44 canbe a manually operated device comprised of a pair of rails 54 mounted tothe overhead sub-module and also attached to the lift device 46 via oneor more sliding members 60 or rolling members 56. The gantry device 44is manually operated. Specifically, the cart carrier 32 includes one ormore handles 52 for allowing the crewmember to move the cart carrier 32,the galley cart 20, and the lift device 46 along the rails 54. Inanother embodiment, the gantry device 44 is a motorized device. Thesequence then proceeds to step 210.

In step 210, the crewmember moves the galley cart 20 along the secondaxis 28 from the cart carrier 32 to the open section of the storage area30. This step is accomplished by the crewmember grabbing hold of thegalley cart 20 through the opening 40 of the cart carrier 32 and pushingor pulling the galley cart 20 onto the available section of the storagearea 30. However, as exemplified above, this step can be accomplishedutilizing various un-lading mechanisms integrated within the cartcarrier 32 as desired.

It will be appreciated that a crewmember can retrieve a galley cart 20from the storage area 30 by reversing the order of steps 200-210.

While particular embodiments of the invention have been shown anddescribed, numerous variations and alternate embodiments will occur tothose skilled in the art. Accordingly, it is intended that the inventionbe limited only in terms of the appended claims.

1-21. (canceled)
 22. A deployable receptacle comprising: a tray forsupporting an object thereon and being movable between a storingposition and a deploying position, said tray storing an object thereonwhen said tray is disposed in said storing position and deploying saidobject therefrom when said tray is disposed in said deploying position;and a lever coupled to said tray for moving said tray between saidstoring position and said deploying position; wherein said tray has adistal end portion and a proximal end portion opposite to said distalend portion, said lever includes a force arm, a resistance arm, and afulcrum portion therebetween, said resistance arm being coupled to saiddistal end portion of said tray.
 23. The deployable receptacle recitedin claim 22 wherein said tray includes at least one supporting surfacefor supporting said object.
 24. The deployable receptacle recited inclaim 23 wherein said at least one supporting surface is substantiallyhorizontal when said tray is disposed in said storing position and saidat least one supporting surface is tilted at a predetermined angle whensaid tray is disposed in said deploying position.
 25. The deployablereceptacle recited in claim 23 wherein said at least one supportingsurface is a pan portion of said tray for supporting a series of wheelsextending from said object and allowing said series of wheels to rollthereon.
 26. The deployable receptacle recited in claim 23 wherein saidat least one supporting surface is a pair of opposing ledge portions ofsaid tray with a series of rolling members coupled thereto, said seriesof roller members for contacting a bottom portion of said object andmoving said object thereacross.
 27. (canceled)
 28. The deployablereceptacle recited in claim 22 wherein said resistance arm of said leveris substantially horizontal when said tray is disposed midway betweensaid storing position and said deploying position thereby minimizing anangle rotation of said lever and maximizing a height change of saiddistal portion of said tray when said lever is actuated to move saidtray from said storing position to said deploying position.
 29. Thedeployable receptacle recited in claim 22 further comprising: a distalanchor member coupled to said fulcrum portion of said lever; and aproximal anchor member coupled to said proximal end portion of saidtray.
 30. The deployable receptacle recited in claim 29 wherein saiddistal anchor member and said proximal anchor member comprise aone-piece base for mounting said tray thereon.
 31. The deployablereceptacle recited in claim 29 wherein said proximal anchor member ispivotally coupled to said proximal end portion of said tray, saidproximal end portion moving along an arcuate path when said tray ismoved between said storing position and said deploying position.
 32. Thedeployable receptacle recited in claim 29 wherein said proximal endportion of said tray is slidably coupled to said proximal anchor memberso as to allow said proximal end portion to move in a substantiallyhorizontal path.
 33. The deployable receptacle recited in claim 29wherein said proximal anchor portion of said base member is coupled tosaid proximal end portion of said tray via at least one of a pin andslot fastening pair and a linkage bar.
 34. A deployable receptaclecomprising: a tray for supporting an object thereon and being movablebetween a storing position and a deploying position, said tray storingan object thereon when said tray is disposed in said storing positionand deploying said object therefrom when said tray is disposed in saiddeploying position; and a lever coupled to said tray for moving saidtray between said storing position and said deploying position, saidlever being coupled to at least one of a solenoid device, a hydraulicdevice, an electronic servo device, and a pedal portion for actuation bya person. 35-40. (canceled)
 41. The deployable receptacle recited inclaim 34 wherein said tray includes at least one supporting surface forsupporting said object.
 42. The deployable receptacle recited in claim41 wherein said at least one supporting surface is substantiallyhorizontal when said tray is disposed in said storing position and saidat least one supporting surface is tilted at a predetermined angle whensaid tray is disposed in said deploying position.
 43. The deployablereceptacle recited in claim 41 wherein said at least one supportingsurface is a pan portion of said tray for supporting a series of wheelsextending from said object and allowing said series of wheels to rollthereon.
 44. The deployable receptacle recited in claim 41 wherein saidat least one supporting surface is a pair of opposing ledge portions ofsaid tray with a series of rolling members coupled thereto, said seriesof roller members for contacting a bottom portion of said object andmoving said object thereacross.
 45. The deployable receptacle recited inclaim 34, wherein said tray has a distal end portion and a proximal endportion opposite to said distal end portion, said lever includes a forcearm, a resistance arm, and a fulcrum portion therebetween, saidresistance arm being coupled to said distal end portion of said tray andis substantially horizontal when said tray is disposed midway betweensaid storing position and said deploying position thereby minimizing anangle rotation of said lever and maximizing a height change of saiddistal portion of said tray when said lever is actuated to move saidtray from said storing position to said deploying position.
 46. Thedeployable receptacle recited in claim 45 further comprising: a distalanchor member coupled to said fulcrum portion of said lever; and aproximal anchor member coupled to said proximal end portion of saidtray.
 47. The deployable receptacle recited in claim 46 wherein saiddistal anchor member and said proximal anchor member comprise aone-piece base for mounting said tray thereon.
 48. The deployablereceptacle recited in claim 46 wherein said proximal anchor member ispivotally coupled to said proximal end portion of said tray, saidproximal end portion moving along an arcuate path when said tray ismoved between said storing position and said deploying position.
 47. Thedeployable receptacle recited in claim 46 wherein said proximal endportion of said tray is slidably coupled to said proximal anchor memberso as to allow said proximal end portion to move in a substantiallyhorizontal path.
 48. The deployable receptacle recited in claim 46wherein said proximal anchor portion of said base member is coupled tosaid proximal end portion of said tray via at least one of a pin andslot fastening pair and a linkage bar.